Solid state relay blows the fuses in my speakers

• Solid state relay blows the fuses in my speakers
  Posted by szekelyisz on 31 May, 2022 00:56
• Hi everybody,
  
  I want to turn my active studio monitors on and off with a solid state relay. I wired up everything, and it worked as it should for about a day, but then suddenly both my speakers' fuses blew. I replaced one of them, turned it on, worked fine. Then I replaced the other one, powered it up, and after a couple seconds both blew again. The SSR works fine, tested it with a light. I'm wondering if the issue has anything to do with the SSR. Before if worked fine for months connected directly to the electric network (no relay). What do you think?
  
  Thanks!
• #1 Reply
  Posted by NiHaoMike on 31 May, 2022 01:00
• Sounds like a defective SSR that's creating a DC offset under some conditions.
• #2 Reply
  Posted by Circlotron on 31 May, 2022 03:06
• DC offset would only matter if the PSU it was feeding had a transformer. If SMPS then shouldn't care.
• #3 Reply
  Posted by NiHaoMike on 31 May, 2022 03:23
• Quote from: Circlotron on 31 May, 2022 03:06

  DC offset would only matter if the PSU it was feeding had a transformer. If SMPS then shouldn't care.
  

  Linear power supplies are still very common in audio equipment.
• #4 Reply
  Posted by Circlotron on 31 May, 2022 05:36
• Quote from: NiHaoMike on 31 May, 2022 03:23

  Linear power supplies are still very common in audio equipment.
  

  That's true, especially for stand alone amplifiers. But for an active speaker I imagine SMPSs are common nowadays, but not universal of course.
• #5 Reply
  Posted by Gyro on 31 May, 2022 08:47
• It sounds as if you are using an SSR that switches on a mains zero-crossings. This is fine for resistive loads, but will cause a transformer in a linear supply (if it is a linear supply) to saturate on every switch on. If this happens every time you switch them on, it will stress the fuses until they ultimately fail.
  
  You can get 'random switching' SSRs that turn on as soon as they receive the control signal, rather than waiting for the next zero crossing.
• #6 Reply
  Posted by Zero999 on 31 May, 2022 11:21
• A random firing SSR will improve things, but it's not guaranteed never to turn on at zero. You want to turn on at the peak voltage, or add a soft start, such as a NTC (Negative Temperature Resistor) or another timer relay which bypasses a current limiting resistor after a few hundred ms.
• #7 Reply
  Posted by szekelyisz on 31 May, 2022 13:35
• Thank you guys! It is a linear PSU and the SSR has zero crossing detection. I'll get a random firing one.
• #8 Reply
  Posted by jonpaul on 31 May, 2022 22:27
• Chinese SSR are junk, poor reliability and performance
  
  Use the EU or USA brand not Chinese knockoffs
  
  j
• #9 Reply
  Posted by Zero999 on 01 Jun, 2022 07:09
• Quote from: jonpaul on 31 May, 2022 22:27

  Chinese SSR are junk, poor reliability and performance
  
  Use the EU or USA brand not Chinese knockoffs
  
  j
  

  Are you sure you're responding in the correct thread? Nothing was mentioned of Chinese knockoffs here. The same thing could happen with high quality products made in Germany. Transformers are known to blow fuses, especially when turned on during the zero crossing point.  Toroidal transformer, which are more commonly found in high quality audio products are especially prone to this.
• #10 Reply
  Posted by jonpaul on 01 Jun, 2022 07:53
• Rebonjour, The SSR market like others has been affected by shortages.
  
  Counterfeit SSRs are rife. Most counterfeits have very poor safety and reliability and performance.
  
  Question to OP is the model/photo/mfg of the SSR in question.
  
  Original genuine or knockoff?
  
  Enjoy!
  
  
  Jon
• #11 Reply
  Posted by Zero999 on 01 Jun, 2022 08:44
• Quote from: jonpaul on 01 Jun, 2022 07:53

  Rebonjour, The SSR market like others has been affected by shortages.
  
  Counterfeit SSRs are rife. Most counterfeits have very poor safety and reliability and performance.
  
  Question to OP is the model/photo/mfg of the SSR in question.
  
  Original genuine or knockoff?
  
  Enjoy!
  
  
  Jon
  

  How would a cheap knockoff SSR cause the fuse to blow in this instance?
  
  The original poster said it is a linear PSU and the SSR has zero crossing detection. He would get the same result whether the SSR is a cheap knockoff, or a branded one from Germany.
• #12 Reply
  Posted by jonpaul on 01 Jun, 2022 12:03
• Zero999
  inductive loads can saturate with any DC bias, like a mains transformer
  
  SSRs have SCR, Triaacs, even a perfect zero cross firings may not reliablely prevent all DC bias eg asymmetrical Vfwd.
  
  Poor quality snubber RC or no snubber is another possibility
  
  Jon
• #13 Reply
  Posted by Zero999 on 01 Jun, 2022 12:20
• Quote from: jonpaul on 01 Jun, 2022 12:03

  Zero999
  inductive loads can saturate with any DC bias, like a mains transformer
  
  SSRs have SCR, Triaacs, even a perfect zero cross firings may not reliablely prevent all DC bias eg asymmetrical Vfwd.
  
  Poor quality snubber RC or no snubber is another possibility
  
  Jon
  

  You're missing the point: zero crossing increases the risk of a transformer blowing the fuse!
  
  I take your point about asymmetric forward voltage drop, but the fact the original poster was using an SSR with zero-crossing is more likely to be the cause and needs to be ruled out first.
  
  Either way, I'd drop the SSR, use an ordinary mechanical relay and add an NTC resistor, to limit the surge.
• #14 Reply
  Posted by jonpaul on 01 Jun, 2022 12:53
• Zero999, ACK, 100% agree.
  
  We used double break relays, wired for arc blowout.
  
  very likely no thermistor needed if load is under 100w
  
  large multi KVA need a contactor....
  
  Still think the Chinese SSR are failure prone....
  
  Bon journée
  
  Jon
• #15 Reply
  Posted by Doctorandus_P on 01 Jun, 2022 13:14
• The fuses should not blow, even with an SSR.
  If the fuses blow because the SSR switches at the zero crossing, there is some serious design flaw with those amplifiers.
  
  A DC bias form the SSR's seems more likely, especially if it takes some time between turning it on and blowing the fuses.
• #16 Reply
  Posted by bdunham7 on 01 Jun, 2022 13:26
• Quote from: Zero999 on 01 Jun, 2022 12:20

  You're missing the point: zero crossing increases the risk of a transformer blowing the fuse!
  
  I take your point about asymmetric forward voltage drop, but the fact the original poster was using an SSR with zero-crossing is more likely to be the cause and needs to be ruled out first.
  
  Either way, I'd drop the SSR, use an ordinary mechanical relay and add an NTC resistor, to limit the surge.
  

  
  In the OP it is stated that the problem occurred after a day of use, and that the fuse was subsequently observed to blow 'after several seconds'.  That's not a turn-on issue.  He also stated that the amplifiers had been working normally before the SSR was installed.  I'm going to guess that a different SSR will solve the issue, but not because it is not zero-crossing. 
• #17 Reply
  Posted by Zero999 on 01 Jun, 2022 13:35
• Quote from: bdunham7 on 01 Jun, 2022 13:26

  Quote from: Zero999 on 01 Jun, 2022 12:20

  You're missing the point: zero crossing increases the risk of a transformer blowing the fuse!
  
  I take your point about asymmetric forward voltage drop, but the fact the original poster was using an SSR with zero-crossing is more likely to be the cause and needs to be ruled out first.
  
  Either way, I'd drop the SSR, use an ordinary mechanical relay and add an NTC resistor, to limit the surge.
  

  
  In the OP it is stated that the problem occurred after a day of use, and that the fuse was subsequently observed to blow 'after several seconds'.  That's not a turn-on issue.  He also stated that the amplifiers had been working normally before the SSR was installed.  I'm going to guess that a different SSR will solve the issue, but not because it is not zero-crossing.
  

  Fuses can wear out over time.
  
  The original poster didn't say whether it's happening on turn on, or not.
  
  It could be the zero crossing, the SSR's asymmetry, or both. It is easy to jump to conclusions and I admit I've been guilty of that plenty of times.
• #18 Reply
  Posted by jonpaul on 01 Jun, 2022 15:18
• We can save time on speculation if the OP can just provide more details of the SSR used, and amplifier.
  
  Model #s, a diagram and photos will be useful
  
  Jon
• #19 Reply
  Posted by tooki on 01 Jun, 2022 15:21
• Are they fast-blow fuses? If so, is this a situation where using slow-blow fuses would be a viable solution? (I don’t have enough background in magnetics to understand the mechanics of the transformer saturation problem, hence the question.)
• #20 Reply
  Posted by CaptDon on 01 Jun, 2022 18:14
• Someone enlighten me on why zero crossing turn-on blows fuses with transformers as the load? We always used zero-crossing SSR's in industry to turn on inductive loads. Connecting a transformer during the peak voltage point is sure to cause a huge inrush fuse blowing event! Our safest SSR devices for transformer and inductive loads had an internal bridge rectifier and SCR as opposed to the triac models. The bridge/SCR units were less likely to cause D.C. offset as compared to triac models. For some of the high current (more than 10 amps) devices we created our own bridge/SCR SSR packages. With a really terrible power factor sometimes the turn-off events were weird. I suppose with an inductive load a zero crossing SSR could be bad in a dimming/power regulation application? Our usage simply called for full-on or full-off which is what I supposed is the original posters application.
  
  
• #21 Reply
  Posted by Gyro on 01 Jun, 2022 18:37
• Quote from: CaptDon on 01 Jun, 2022 18:14

  Someone enlighten me on why zero crossing turn-on blows fuses with transformers as the load?
  

  
  Transformers usually rely on some collapsing residual magnetisation from the previous half-cycle to prevent their cores from saturating at mains peak. If you power them on at a mains voltage zero crossing, they will tend to saturate on the first peak, causing a high current surge, limited only by the primary DC resistance. The size of the surge depends on the size of the transformer, how close the transformer is to saturating in normal operation (quality / 'economy'), and type (torroidal tend to run closer to saturation).
  
  

  Quote

  Connecting a transformer during the peak voltage point is sure to cause a huge inrush fuse blowing event!
  

  
  Actually, no. A transformer is inductive, so current lags voltage by quite a margin. Current will rise relatively slowly on a fast voltage step, and the core won't have time to saturate before the voltage has dropped away.
  
  At one point I worked in traffic control systems. The halogen lamp head transformers would audibly 'bong' and cause structural resonance when switched at zero crossing. They also suffered high failure rate. Shifting the triac switching point away from the zero crossing cured both.
• #22 Reply
  Posted by CaptDon on 01 Jun, 2022 20:18
• Interesting, the current rise time with high peak voltage turn-on relationship. I work very often with a particular 1Khz switch speed SMPS and since the SMPS transformer is never allowed to go anywhere near saturation (It has a lot of built in safety margin to unusually high line voltages and long PWM pulse widths at low line) we see a very nice linear current ramp up with a nice clean turnoff. The voltages on the drains of the mosfets on the other hand look horrible!!! The O.E.M. has released a few snubber mods!!! Excessively high ring voltage peaks were killing the mosfets. There was a lot of capacitor energy storage ahead of the transformer, and the transformer had very low primary D.C. resistance. The mosfets left town in a spectacular way when they shorted!!
  
• #23 Reply
  Posted by Circlotron on 01 Jun, 2022 22:20
• For a transformer that is already running in a steady state, a half cycle of voltage will cause the magnetism in the core to go from fully south to full north. If the transformer is switched on at the voltage zero crossing the core magnetism starts at zero instead of fully south and so by the time the voltage gets to the 90 degree peak the magnetism has already reached fully north and for the remaining 90 degrees of voltage it cannot increase further and so the core saturates and the current goes off the planet.
• #24 Reply
  Posted by Zero999 on 01 Jun, 2022 22:45
• In an ideal inductor, the startup current is double if the waveform starts at zero, compared to what it would be if it starts at the peak voltage.
  

  ---

  Inductor inrush.asc